IF statement having an expression setup clause to be utilized in structured assembly language programming

ABSTRACT

A state machine for an assembler capable of processing structured assembly language is disclosed. The state machine for an assembler capable of processing structured assembly language IF constructs includes five states, namely, an IF state, an ELSE state, an END — IF state, an ELSE — IF state, and a SETUP — IF state. In response to recognizing a SETUP — IF clause during the IF state or the ELSE — IF state, the process transitions to the SETUP — IF state. In response to recognizing an ELSE — IF clause during the SETUP — IF state, the process transitions to the ELSE — IF state.

BACKGROUND OF THE INVENTION

1. Technical Field

The present invention relates to assembly programming in general, and in particular to structured assembly language programming. Still more particularly, the present invention relates to an IF construct having an expression setup clause to be utilized in structured assembly language programming.

2. Description of the Prior Art

Structured assembly language programming is an improvement to the basic syntax of conventional assembly language programming. In essence, structured assembly language programming allows the use of structured programming constructs similar to those generally found in high-level programming languages such as Pascal or C.

One of the structured programming constructs is the well-known IF construct. It consists of an IF clause followed by zero or more ELSE_(—)IF clauses, an optional ELSE clause, and an END_(—)IF statement. The simplest structured assembly language IF construct is typically utilized as follows:

condition setup assembly language code IF (condition) conditionally executed assembly language code END_(—)IF unassociated with IF assembly language code where condition contains structured assembly language expression(s) for generating comparison opcodes (i.e., opcodes that set the processor's flags) and/or branch opcodes. Only comparison opcodes and branch opcodes are used in the implementation of a structured assembly language expression. An assembler then converts the above-mentioned structured assembly language IF construct to a group of processor opcodes as follows (in assembler mnemonics):

condition setup assembly language code cmp r0,#7 ; (r0 == 7) ∥ (r1 < r2) bnz falselabel cmp r1,r2 bge falselabel conditionally executed assembly language code falselabel equ $ In this example, the condition compares a processor register to a numeric value, and a comparison also occurs between two processor registers. The condition is (r0==7) or (r1<r2). One important difference between a structured assembly language IF construct and an IF construct from a high-level programming language is that a programmer is responsible for register setup so the structured assembly language expression, that is the condition, is only made up of comparison opcodes and/or branch opcodes. In fact, such kind of optimization capability is a key reason for choosing assembly language in the first place. The need to execute opcodes to setup for a structured assembly language expression is a real problem when multiple conditions must be tested. In order to test many different conditions using structured assembly language under the prior art, a nested testing scheme is required, and the code will resemble the following:

condition setup code1 IF (condition1) conditionally executed code1 ELSE condition setup code2 IF (condition2) conditionally executed code2 ELSE condition setup code3 IF (condition3) conditionally executed code3 ELSE condition setup code4 IF (condition4) conditionally executed code4 ELSE condition setup code5 IF (condition5) conditionally executed code5a ELSE conditionally executed code5b END_(—)IF END_(—)IF END_(—)IF END_(—)IF END_(—)IF

It becomes obvious that multiple testing conditions are awkward to code in structured assembly language when standard programming conventions for indentation are followed. The awkward form of coding also makes the task of understanding code and the task of maintaining code more difficult. Consequently, it would be desirable to provide an improved IF statement to be utilized in structured assembly language programming for coding multiple testing conditions.

SUMMARY OF THE INVENTION

In accordance with a preferred embodiment of the present invention, a state machine for an assembler capable of processing structured assembly language IF constructs includes five states, namely, an IF state, an ELSE state, an END_(—)IF state, an ELSE_(—)IF state, and a SETUP_(—)IF state. In response to recognizing a SETUP_(—)IF clause during the IF state or the ELSE_(—)IF state, the process transitions to the SETUP_(—)IF state. In response to recognizing an ELSE_(—)IF clause during the SETUP_(—)IF state, the process transitions to the ELSE_(—)IF state.

All objects, features, and advantages of the present invention will become apparent in the following detailed written description.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention itself, as well as a preferred mode of use, further objects, and advantages thereof, will best be understood by reference to the following detailed description of an illustrative embodiment when read in conjunction with the accompanying drawings, wherein:

FIG. 1 is a state machine for the standard structured assembly language IF construct;

FIG. 2 is a state machine for a structured assembly language IF construct in accordance with a preferred embodiment of the present invention;

FIG. 3 is a block diagram of an assembler to which a preferred embodiment of the present invention can be applied; and

FIG. 4 is a block diagram of a computer system to which a preferred embodiment of the present invention can be applied.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT

A more specific example of nested testing, using a standard programming indentation convention, is shown below:

1dr r0, [r2+0] ;0 IF (r0 <ne> #7) add r1,#1 ELSE 1dr r0, [r2+3] ;1 IF (r0 <ge> #3) add r1,#2 ELSE 1dr r0, [r2+5] ;2 IF (r0 <1e> #1) add r1, #3 ELSE add r1,#4 END_(—)IF END_(—)IF END_(—)IF

A careful examination of the above-shown nested testing reveals that each IF construct is inside an ELSE clause. Thus, the logic is really IF-ELSEIF-ELSEIF . . . ENDIF. Unfortunately, the nested structured assembly language IF constructs hide this fact.

In accordance with a preferred embodiment of the present invention, a SETUP_(—)IF clause is introduced to eliminate the confusion caused by the nested IFs, and to restore the logic to a form that truly represents what is happening. The modified IF construct using the SETUP_(—)IF clause consists of an IF clause followed by an optional SETUP_(—)IF clause preceding an ELSE_(—)IF clause, an optional ELSE clause, and an END_(—)IF statement. The pair of clauses, an optional SETUP_(—)IF clause followed by an ELSE_(—)IF clause, may appear zero or more times immediately following the IF clause, as follows:

condition setup code1 IF (condition1) conditionally executed code1 SETUP_(—)IF ;branch endif, label for “condition1 is false” condition setup code2 ELSE_(—)IF (condition2) conditionally executed code2 SETUP_(—)IF ;branch endif, label for “condition2 is false” condition setup code3 ELSE_(—)IF (condition3) conditionally executed code3 SETUP_(—)IF ;branch endif, label for “condition3 is false” condition setup code4 ELSE_(—)IF (condition4) conditionally executed code4 ELSE_(—)IF (condition5) conditionally executed code5a ELSE ;branch endif, label for “condition5 is false” conditionally executed code5b END_(—)IF ;label for endif, label for “condition6 is false” The SETUP_(—)IF statement, at the start of the SETUP_(—)IF clause, is converted by an assembler to a branch to END_(—)IF label. The SETUP_(—)IF statement will also define the falselabel needed by the previous structured assembly language expression. If condition1 is true, code1 is then executed. The branch END_(—)IF code generated by the SETUP_(—)IF statement immediately following the IF clause is then executed. If condition 1 is false, the code for condition1 will branch to the falselabel1 generated by the SETUP IF statement immediately following the IF clause. Execution will continue with setup code2. The above-mentioned pattern is repeated for all instances of the SETUP_(—)IF clause in the modified structured assembly language IF construct.

The above-mentioned multiple testing condition example can be coded using SETUP_(—)IF clauses, as follows:

1dr r0, [r2+0] ;0 IF (r0 <ne> #7)   add r1,#1 SETUP_(—)IF   1dr r0, [r2+3] ;1 ELSE_(—)IF (r0 <ge> #3)   add r1,#2 SETUP_(—)IF   1dr r0, [r2+5] ;2 ELSE_(—)IF (r0 <1e> #1)   add r1,#3 ELSE   add r1,#4 END_(—)IF Compared with the previous code, the new code does not have a requirement for the programmer to balance multiple IF with multiple END_(—)IF statements. Thus, without the present invention, each condition tested requires the assembler to keep and to track an instance of an IF construct. But with the present invention, only a single IF construct is required. Because structured assembly language, like structured programming, is block-oriented, each new IF statement is a new unique block. Each structured assembly language block requires the assembler to track the state of the a block, to generate and remove the block and its related information, and to allocate and consume assembler resources. Fewer nested structured assembly language blocks means fewer resources are required by the assembler.

Generally speaking, structured assembly language is implemented through program labels, pattern generated code, a stack for structured programming blocks, and a simple state machine for each different type of structured assembly language construct. The structured assembly language IF construct is no exception. Thus, the present invention can also be compared with the prior art from a state machine point of view. The state machine for the standard structured assembly language IF construct is depicted in FIG. 1. As shown, a state machine x has four states, namely, an IF state, an ELSE state, an END_(—)IF state, and an ELSE_(—)IF state. Each state represents a clause in an IF construct. Steps and actions for each state are summarized in Table I.

TABLE I State Description of Steps for state IF 1) Push new block on structured assembly block stack 2) Generate a new and unique NextClauseLabel (false label) 3) Generate EndIfLabel 4) Emit opcode(s) for condition ELSEIF 1) Emit jump to EndIfLabel 2) Set NextClauseLabel (next false label) 3) Generate a new and unique NextClauseLabel (false label) 4) Emit opcode(s) for condition ELSE 1) Emit jump to EndIfLabel 2) Set NextClauseLabel (false label) ENDIF 1) Set NextClauseLabel (false label) 2) Set EndIfLabel 3) Pop current block off structured assembly block stack

In accordance with a preferred embodiment of the present invention, the state machine of the present invention is depicted in FIG. 2. As shown, a state machine y has five states, namely, an IF state, an ELSE state, an END_(—)IF state, an ELSE_(—)IF state, and a SETUP_(—)IF state. Each state represents an IF construct clause. Steps and actions for each state is summarized in Table II.

TABLE II State Description of Steps for state Status IF 1) Push new block on structured unchanged assembly block stack 2) Generate NextClauseLabel (false label) 3) Generate EndIfLabel 4) Emit opcode(s) for condition SETUP 1) Emit jump to EndIfLabel new 2) Set NextClauseLabel (false label) 3) Generate a new and unique Next ClauseLabel (false label) ELSEIF 1) Emit jump to EndIfLabel if previous modified state was not setup 2) Set NextClauseLabel 3) Generate a new and unique NextClauseLabel (false label) 4) Emit opcode(s) for condition ELSE 1) Emit jump to EndIfLabel unchanged 2) Set NextClauseLabel ENDIF 1) Set NextClauseLabel unchanged 2) Set EndIfLabel 3) Pop current block off structured assembly block stack

One of the virtues of structured assembly programming is that the internal structures representing constructs in structured assembly language can be stored in a stack. Each structured assmebly language construct or block needs to be indentified by a type, and the construct's internal state needs to be recorded, and two labels are required, one label for the next clause and one label for the end of the construct. The manipulation of those values is shown in Table I and Table II. As shown, the nature of the elements in a tuple that holds the state of the IF construct state machine remains unchanged.

The relationship between the state values of a structured assembly language construct and an assembler is shown in FIG. 3, there is illustrated a block diagram of an assembler to which a preferred embodiment of the present invention can be applied. As shown, an assembler 30 includes a lexer 32, a parser 33, and a code generator 34. User source files 31 are broken down into tokens by lexer 32. Groups of tokens are recognized as statements in the grammar of the programming language by parser 33. Internal structures built up by parser 33 and lexer 32 are then processed into code by code generator 34, thereby generating listing and binary image files that are the work product of assembler 30.

An assembler, such as assembler 30, capable of processing structured assembly language may be executed in a variety of data processing systems under a number of different operating systems. The computer may be, for example, a personal computer, a midrange computer or a mainframe computer. In addition, the computer may be a stand-alone system or part of a network such as a local-area network (LAN) or a wide-area network (WAN).

With reference now to FIG. 4, there is depicted a block diagram of a computer system 10 in which a preferred embodiment of the present invention is applicable. As shown, a processor 12, a read-only memory (ROM) 13, and a random access memory (RAM) 14 are connected to a system bus 11. Processor 12, ROM 13, and RAM 14 are also coupled to a peripheral component interconnect (PCI) bus 20 of computer system 10 through a PCI host bridge 16. PCI host bridge 16 provides a low latency path through which processor 12 may directly access PCI devices mapped anywhere within bus memory and/or I/O address spaces. PCI host bridge 16 also provides a high bandwidth path allowing PCI devices to directly access RAM 14.

In addition, an audio adapter 23 and a graphics adapter 21 may be attached to PCI bus 20. Graphics adapter 21 controls visual output through a video monitor 22 and 25 audio adapter 20 controls audio output through a speaker 24. Also attached to PCI bus 20 is a communications adapter 15 and a small computer system interface (SCSI) 18. Communications adapter 15 connects computer system 10 to a local-area network (LAN) 17. SCSI 18 is utilized to control a high-speed SCSI disk drive 19. Expansion bus bridge 29, such as a PCI-to-ISA bus bridge, may be utilized for coupling an industry standard architecture (ISA) bus 25 to PCI bus 20. As shown, a keyboard 26 and a mouse 28 are attached to ISA bus 25 for performing certain basic I/O functions.

As has been described, the present invention provides a SETUP_(—)IF clause, which is an ELSE_(—)IF clause having an expression setup clause, to be utilized in structured assembly language programming.

It is also important to note that although the present invention has been described in the context of a fully functional computer system, those skilled in the art will appreciate that the mechanisms of the present invention are capable of being distributed as a program product in a variety of forms, and that the present invention applies equally regardless of the particular type of signal bearing media utilized to actually carry out the distribution. Examples of signal bearing media include, without limitation, recordable type media such as floppy disks or CD ROMs and transmission type media such as analog or digital communications links.

While the invention has been particularly shown and described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention. 

1. A computer program product residing on a computer recordable medium for processing structured assembly language, said computer program product comprising: program code means for implementing a state machine having an IF state, an ELSE state, an END_(—)IF state, an ELSE_(—)IF state, and a SETUP_(—)IF state; program code means for transitioning from said IF state or said ELSE_(—)IF state to said SETUP_(—)IF state, in response to recognizing a SETUP_(—)IF clause; and program code means for transitioning from said SETUP_(—)IF state to said ELSE_(—)IF state, in response to recognizing an ELSE_(—)IF clause.
 2. The computer program product of claim 1, wherein said computer program product further includes program code means for transitioning from said IF state to said ELSE state, in response to recognizing an ELSE clause.
 3. The computer program product of claim 1, wherein said computer program product further includes program code means for transitioning from said IF state to said END_(—)IF state, in response to recognizing an END_(—)IF statement.
 4. The computer program product of claim 1, wherein said computer program product further includes program code means for transitioning from said IF state to said ELSE_(—)IF state, in response to recognizing an ELSE_(—)IF clause.
 5. The computer program product of claim 1, wherein said computer program product further includes program code means for transitioning from said ELSE state to said END_(—)IF state, in response to recognizing an END_(—)IF statement.
 6. The computer program product of claim 1, wherein said computer program product further includes program code means for transitioning from said ELSE_(—)IF state to said END_(—)IF state, in response to recognizing an END_(—)IF statement.
 7. The computer program product of claim 1, wherein said computer program product further includes program code means for transitioning from said ELSE_(—)IF state to said ELSE state, in response to recognizing an ELSE clause.
 8. A data processing system having an assembler for processing structured assembly language, said data processing system comprising: a state machine having an IF state, an ELSE state, an END_(—)IF state, an ELSE_(—)IF state, and a SETUP_(—)IF state; means for transitioning from said IF state or said ELSE_(—)IF state to said SETUP_(—)IF state, in response to recognizing a SETUP_(—)IF clause; and means for transitioning from said SETUP_(—)IF state to said ELSE_(—)IF state, in response to recognizing an ELSE_(—)IF clause.
 9. The data processing system of claim 8, wherein said data processing system further includes means for transitioning from said IF state to said ELSE state, in response to recognizing an ELSE clause.
 10. The data processing system of claim 8, wherein said data processing system further includes means for transitioning from said IF state to said END_(—)IF state, in response to recognizing an END_(—)IF statement.
 11. The data processing system of claim 8, wherein said data processing system further includes means for transitioning from said IF state to said ELSE_(—)IF state, in response to recognizing an ELSE_(—)IF clause.
 12. The data processing system of claim 8, wherein said data processing system further includes means for transitioning from said ELSE state to said END_(—)IF state, in response to recognizing an END_(—)IF statement.
 13. The data processing system of claim 8, wherein said data processing system further includes means for transitioning from said ELSE_(—)IF state to said END_(—)IF state, in response to recognizing an END_(—)IF statement.
 14. The data processing system of claim 8, wherein said data processing system further includes means for transitioning from said ELSE_(—)IF state to said ELSE state, in response to recognizing an ELSE clause.
 15. An assembler residing in a data processing system for processing structured assembly language, said assembler comprising: means for implementing a state machine having an IF state, an ELSE state, an END IF state, an ELSE IF state, and a SETUP IF state: means for identifying a, SETUP_(—)IF clause; means for associating said identified SETUP_(—)IF clause with an ELSE_(—)IF clause having a test condition; and means for inserting instructions from said identified SETUP_(—)IF clause prior to the test condition of said ELSE_(—)IF clause where said ELSE_(—)IF clause logically follows a prior IF clause or a prior ELSE_(—)IF clause.
 16. A computer program product residing on a computer recordable medium for processing structured assembly language, said computer program product comprising: program code means for implementing a state machine having an IF state, an ELSE state, an END_(—)IF state, an ELSE_(—)IF state, and a SETUP_(—)IF state; program code means for identifying a SETUP_(—)IF clause; program code means for associating said identified SETUP_(—)IF clause with an ELSE_(—)IF clause having a test condition; and a program code means for inserting instructions from said identified SETUP_(—)IF clause prior to the test condition of said ELSE_(—)IF clause where said ELSE_(—)IF clause logically follows a prior IF clause or a prior ELSE_(—)IF clause. 